A monolithic three dimensional semiconductor device structure includes a first layer including a first occurrence of a first reference mark at a first location, and a second layer including a second occurrence of the first reference mark at a second location, wherein the second location is substantially directly above the first location. The device structure also includes an intermediate layer between the first layer and the second layer, the intermediate layer including a blocking structure, wherein the blocking structure is vertically interposed between the first occurrence of the first reference mark and the second occurrence of the first reference mark. Other aspects are also described.
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1. A monolithic three dimensional semiconductor device structure comprising:
a first layer including a first occurrence of a first reference mark at a first location;
a second layer including a second occurrence of the first reference mark at a second location, wherein the second location is substantially directly above the first location; and
an intermediate layer between the first layer and the second layer, the intermediate layer including a blocking structure, wherein the blocking structure is vertically interposed between the first occurrence of the first reference mark and the second occurrence of the first reference mark.
12. A monolithic three dimensional memory array comprising:
a) a first memory level, the first memory level comprising a first layer at a first height, the first layer including a first occurrence of a first reference mark;
b) a second memory level, the second memory level comprising a second layer at a second height above the first height, the second layer including a second occurrence of the first reference mark, the second occurrence of the first reference mark formed substantially directly above the first reference mark; and
c) an intervening layer at a third height between the second height and the first height, the intervening layer including a blocking structure, the blocking structure vertically interposed between the first occurrence of the first reference mark and the second occurrence of the first reference mark, wherein the second memory level is monolithically formed above the first memory level.
2. The monolithic three dimensional semiconductor device structure of
3. The monolithic three dimensional semiconductor device structure of
4. The monolithic three dimensional semiconductor device structure of
5. The monolithic three dimensional semiconductor device structure of
6. The monolithic three dimensional semiconductor device structure of
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8. The monolithic three dimensional semiconductor device structure of
9. The monolithic three dimensional semiconductor device structure of
10. The monolithic three dimensional semiconductor device structure of
11. The monolithic three dimensional semiconductor device structure of
13. The monolithic three dimensional memory array of
14. The monolithic three dimensional memory array of
15. The monolithic three dimensional memory array of
16. The monolithic three dimensional memory array of
17. The monolithic three dimensional memory array of
18. The monolithic three dimensional memory array of
19. The monolithic three dimensional memory array of
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This application is a division of U.S. patent application Ser. No. 11/097,496, filed Mar. 31, 2005, now U.S. Pat. No. 7,553,611, which is incorporated by reference herein in its entirety.
The invention relates to a method to avoid interference between recurring alignment and overlay marks formed when a photomask is reused at different vertical heights in fabrication of an integrated circuit.
In conventional integrated circuit design, it is not usual to reuse a photomask. In some complex structures, however, it may be most cost-effective to use the same photomask more than once. When a photomask is reused, the reference marks (alignment and overlay marks) used to align the following photomask and to check the alignment achieved are reproduced in almost exactly the same location as in the first use of the mask. The prior reference marks can interfere with the present reference marks.
There is a need, therefore, for a way to reuse photomasks while preventing interference between recurring reference marks.
In a first aspect of the invention, a monolithic three dimensional semiconductor device structure is provided that includes a first layer including a first occurrence of a first reference mark at a first location, and a second layer including a second occurrence of the first reference mark at a second location, wherein the second location is substantially directly above the first location. The device structure also includes an intermediate layer between the first layer and the second layer, the intermediate layer including a blocking structure, wherein the blocking structure is vertically interposed between the first occurrence of the first reference mark and the second occurrence of the first reference mark.
In a second aspect of the invention, a monolithic three dimensional memory array is provided that includes a first memory level, the first memory level comprising a first layer at a first height, the first layer including a first occurrence of a first reference mark, a second memory level, the second memory level comprising a second layer at a second height above the first height, the second layer including a second occurrence of the first reference mark, the second occurrence of the first reference mark formed substantially directly above the first reference mark, and an intervening layer at a third height between the second height and the first height, the intervening layer including a blocking structure, the blocking structure vertically interposed between the first occurrence of the first reference mark and the second occurrence of the first reference mark, wherein the second memory level is monolithically formed above the first memory level.
In a third aspect of the invention, a method for forming a monolithic three dimensional memory array is provided that includes forming a first memory level, the step of forming the first memory level comprising using a first photomask to form a first layer at a first height, the first layer comprising a first reference mark, forming a second layer at a second height above the first height, the second layer comprising a blocking structure, and forming a second memory level, the step of forming the second memory level comprising using the first photomask to form a third layer at a third height above the second height, the third layer comprising a second reference mark, wherein the blocking structure is vertically interposed between the first reference mark and the second reference mark.
Each of the aspects and embodiments of the invention described herein can be used alone or in combination with one another.
The preferred aspects and embodiments will now be described with reference to the attached drawings.
Features of the present invention can be more clearly understood from the following detailed description considered in conjunction with the following drawings, in which the same reference numerals denote the same elements throughout, and in which:
During fabrication of an integrated circuit, patterned features are conventionally formed using photolithography and etch techniques. To pattern using photolithography, a photomask, which transmits light in some areas and blocks it in others, is formed, the blocking areas corresponding to the pattern (or its inverse) to be formed on the wafer surface. The surface to be patterned, for example a semiconductor, conductive, or dielectric layer, is covered with a layer of photoresist, a photoreactive material. Light is projected onto the photoresist surface using the photomask, selectively exposing areas of photoresist. The wafer is then subjected to a developing process, in which exposed photoresist (or unexposed photoresist, in the case of negative photoresist) is removed, leaving patterned photoresist behind.
The remaining patterned photoresist then typically serves to protect underlying material during a subsequent etch process, creating features in the same pattern as the remaining photoresist.
Formation of a typical integrated circuit will include the use of multiple photomasks, each defining a pattern, each of which must be aligned to the wafer with considerable precision. In some cases, each successive photomask is aligned to a single reference mark on the wafer. In other cases, however, over time this initial reference mark becomes obscured or otherwise undetectable. In this case, each layer can be aligned to a previous patterned layer, ideally the layer formed immediately before it. This form of alignment is called layer-to-layer alignment.
Reference marks used to accomplish and confirm alignment of a photomask come in two types: alignment marks and overlay marks.
The actual shapes of alignment mark and overlay marks vary according to the manufacturer.
After a photomask has been used to expose photoresist and the photoresist has been developed, creating patterned features in the photoresist, a measurement is taken to determine how well the photomask was actually aligned to the reference layer. This measurement is done using overlay marks, which are typically formed in pairs. A target overlay mark is formed in the target layer, the layer being aligned to, while a measured overlay mark is formed in the current layer being aligned. The measured overlay mark, when used for measurement, is formed in photoresist, and is also sometimes referred to as a resist-defined target mark. This discussion will use the term “measured overlay mark,” however, to refer both to the mark as formed in photoresist and to the feature that is left in the underlying layer after the subsequent etch.
Alignment marks and overlay marks are formed outside of the active device area of each die, typically in the scribe lines where the dice will ultimately be cut apart to separate them. The alignment marks and overlay marks of successive layers are formed in different spots so that, for example, alignment marks in successive layers don't interfere with each other. Generally every photomask is unique, so as long as each reference mark is in a unique known location on each photomask, the danger of confusing reference marks from different photomasks can be avoided.
A monolithic three dimensional memory array is described in Herner et al., U.S. patent application Ser. No. 10/326,470, “An Improved Method for Making High Density Nonvolatile Memory,” filed Dec. 19, 2002, since abandoned, hereinafter the '470 application and hereby incorporated by reference. Related memories are described in Herner, U.S. patent application Ser. No. 10/955,549, “Nonvolatile Memory Cell Without a Dielectric Antifuse Having High- and Low-Impedance States,” filed Sep. 29, 2004, hereinafter the '549 application; in Herner et al. U.S. patent application Ser. No. 10/954,577, “Junction Diode Comprising Varying Semiconductor Compositions,” filed Sep. 29, 2004, hereinafter the '577 application; and in Herner et al., U.S. patent application Ser. No. 11/015,824, “Nonvolatile Memory Cell Comprising a Reduced Height Vertical Diode,” filed Dec. 17, 2004, hereinafter the '824 application, all hereby incorporated by reference.
A monolithic three dimensional memory array is one in which multiple memory levels are formed above a single substrate, such as a wafer, with no intervening substrates. The layers forming one memory level are deposited or grown directly over the layers of an existing level or levels. In contrast, stacked memories have been constructed by forming memory levels on separate substrates and adhering the memory levels atop each other, as in Leedy, U.S. Pat. No. 5,915,167, “Three dimensional structure memory.” The substrates may be thinned or removed from the memory levels before bonding, but as the memory levels are initially formed over separate substrates, such memories are not true monolithic three dimensional memory arrays.
A monolithic three dimensional memory array formed above a substrate comprises at least a first memory level formed at a first height above the substrate and a second memory level formed at a second height different from the first height. Three, four, eight, or indeed any number of memory levels can be formed above the substrate in such a multilevel array.
Turning to
The memory cell is formed in an initial high-resistance state, in which little or no current flows when a read voltage is applied. To program a cell, a relatively high programming voltage is applied between the top and bottom conductors. Application of this programming voltage permanently changes the cell, converting it to a low-resistance state, in which a reliably measurable current flows upon application of a read voltage. The difference in current flow on application of a read voltage distinguishes a programmed cell from an unprogrammed cell, and thus a memory “1” from a memory “0.”
Vertically adjacent memory levels may share conductors; i.e. the top conductor of one memory level may serve as the bottom conductor of the next memory level. Alternatively, memory levels may not share conductors, and an interlevel dielectric may be formed separating them.
The memories of the '470, '549, '577, and '824 applications include multiple memory levels like the memory level of
A difficulty arises when reusing photomasks on the same wafer, however. When a photomask is used the second time, exactly the same reference marks are formed, in almost exactly the same locations, as in prior use of the photomask. The earlier and the present reference mark may interfere with each other.
For example,
Fabrication continues, as shown in
As shown in
To prevent this problem, using the methods of the present invention, a blocking structure is formed at an intervening height between the current and previous instances of a reference mark (either an alignment mark or an overlay mark), serving to obscure the previous instance of the mark, so that no interference occurs between them. In
To summarize, what has been described is a method to allow reuse of a first photomask in a monolithically formed stacked vertical structure, the method comprising: using the first photomask to form a first reference mark in a first layer; forming a blocking structure above the first reference mark, wherein the blocking structure serves to obscure the first reference mark when viewed from above; using the first photomask to form a second reference mark in a second layer, the second layer above the first layer and above the blocking structure. The blocking structure can be formed of an opaque material, as described, or as will be seen later, of a semi-opaque material, such as polysilicon. As described, the blocking structure may comprise a series of patterned shapes
The problem could have been avoided by using different photomasks to pattern pillars 300 and pillars 600. These photomasks would be identical in every respect except the placement of the alignment mark. The alignment mark on the second photomask could be placed at a different location, where it would not interfere with the alignment mark created by the first photomask. Photomasks are very expensive, however, making this an unattractive option.
The measured overlay mark, which is formed in photoresist, is on the top layer and is always unobscured. Sometimes, during overlay mark measurement, the target overlay mark is covered solely by transparent material. Silicon dioxide, the dielectric material most commonly used in integrated circuit fabrication, is transparent, and photoresist is nearly transparent. In this case the overlay marks can be located visually. In other cases, however, the reference mark, either the target overlay mark or the alignment mark is covered by one or more layers when the reference mark is to be located, and is not visible.
Often, though, the reference marks can be located using other methods. Reference marks are typically very large and widely spaced compared to the actual patterned features making up the device.
If a blocking structure is to be formed later to mask alignment mark 15, it must render this mark undetectable either optically, or by transferred topography, or both. Thus when this discussion describes a blocking structure as “obscuring” an earlier-formed reference mark, it means that the blocking structure renders that mark undetectable either by visible means or by transferred topography or both.
As an alternative to locating a reference mark by way of transferred topography, if a reference mark is not visible optically, it is also known to perform an open frame etch. Such an etch step etches the obscuring layers in the area of the reference mark only and not in the active device area (e.g. layers 17 and 18 in
The entire structure to be formed, including all process steps, must be considered to determine the appropriate placement and form of blocking structures to prevent interference between recurring reference marks when reusing photomasks. A detailed example will be provided of fabrication of a monolithic three dimensional memory array having four stacked memory levels in which the methods of the present invention are used to allow reuse of photomasks. For completeness, this example will include many details, including materials, dimensions, conditions, and process steps. It will be understood by those skilled in the art that many of these details can be modified, augmented, or omitted while the results still fall within the scope of the invention. This example is provided as an illustration only.
The monolithic three dimensional memory array to be described is similar to that described in the '470, '549, '577, and '824 applications. For simplicity and to avoid obscuring the invention, not all of the detail provided in those applications is included. It will be understood, however, that no teaching of any of the '470, '549, '577, or '824 applications is intended to be excluded.
Fabrication begins with a substrate, preferably a monocrystalline silicon wafer. Before formation of memory levels begins, routing layers are formed above the substrate, including routing layer V1. (For simplicity, not all routing layers are shown.) A conductor photomask, Y0, is used to form bottom conductors 200 of memory level M0. A pillar photomask, BC0, is used to form pillars 300 of memory level M0, and another conductor photomask, X1, is used to form top conductors 400, completing memory level M0. Each of these photomasks is unique. (Names like Y0, BC0, and X1 are used to refer to unique photomasks for clarity, and these names will appear in charts in
Bottom conductors 200, pillars 300, and top conductors 400 together form memory cells, and alignment between them is critical. All of the conductors V1, 200, and 400 and the pillars 300 are formed by subtractive methods, in which a conductive material is deposited, then patterned and etched to leave conductive features. Gaps between the conductive features are filled with dielectric (not shown.)
Similarly, each of pillar photomask BC0 and top conductor photomask X1 is aligned to an alignment mark formed in the immediate previous layer.
Returning to
It will be seen, referring to
Formation of memory level M1 begins with pattern and etch of bottom conductors 500. Due to small differences in how connection is made from zias to bottom conductors 500 of memory level M1 and bottom conductors 200 of memory level M0, the photomasks used to pattern bottom conductors 500 and bottom conductors 200 are not identical. A unique conductor photomask Y2 is used to pattern conductors 500. (Recall that photomask Y0 was used to pattern conductors 200.) Thus no interference takes place between the reference marks of these two layers.
After deposition of a titanium nitride barrier layer and a semiconductor layer stack, pillars 600 will be patterned. Pillar photomask BC0, which was used to pattern pillars 300 in memory level M0, is reused. The alignment mark, target overlay mark, and measured overlay mark formed by photomask BC0 during patterning of pillars 600 are formed directly above the same marks formed during patterning of pillars 300, on the first use of photomask BC0.
The first problem arises on the first attempt to use a repeated overlay mark. Referring to
Turning to
Referring to
What is being formed is a monolithic three dimensional semiconductor device structure comprising a first layer including a first occurrence of a first reference mark at a first location; a second layer including a second occurrence of the first reference mark at a second location, wherein the second location is substantially directly above the first location; and an intermediate layer between the first layer and the second layer, the intermediate layer including a blocking structure, wherein the blocking structure is vertically interposed between the first occurrence of the first reference mark and the second occurrence of the first reference mark.
After completion of pillars 600, another problem may occur with an attempt to use a repeated alignment mark. Referring to
This alignment mark, however, is directly above the first alignment mark created by the first use of photomask BC0 to form pillars 300 of memory level M0. In this example, the current alignment mark formed with pillars 600 is covered by tungsten, which is opaque, so the alignment mark will be located by locating topography transferred through the titanium nitride and tungsten layers. If no intervening blocking structure is formed, topography transferred from the alignment mark patterned with pillars 300 may interfere with the transferred topography from the latest alignment mark patterned with pillars 600.
Referring to
Referring to column 9 of
A plurality of lines is used instead of a solid pad for several reasons. This blocking structure is formed of tungsten. Large tungsten structures tend to peel, while a series of tungsten lines will not.
In addition, structures formed outside of the active device area, including alignment marks, overlay marks, and blocking structures, are exposed to the same processes as structures within the active device area. Referring to
Fabrication continues. Referring to
To summarize, what is described is a method for forming a monolithic three dimensional memory array, the method comprising: a) forming a first memory level, the step of forming the first memory level comprising using a first photomask to form a first layer at a first height, the first layer comprising a first reference mark; b) forming a second layer at a second height above the first height, the second layer comprising a blocking structure; and c) forming a second memory level, the step of forming the second memory level comprising using the first photomask to form a third layer at a third height above the second height, the third layer comprising a second reference mark, wherein the blocking structure is vertically interposed between the first reference mark and the second reference mark.
Referring to
Recall, however, that this is the second use of photomask Y0. Photomask Y0 was used to pattern bottom conductors 200 of memory level M1. Thus the measured overlay mark, in the shape of an inner frame, is formed in photoresist substantially directly above the same measured overlay mark patterned at the level of bottom conductors 200, formed during the first use of photomask Y0. The previously formed measured overlay mark may interfere with the present measured overlay mark.
To prevent this interference, a blocking structure was patterned during patterning of bottom conductors 500. The blocking structure is preferably a plurality of substantially parallel, substantially coplanar lines in an area large enough to obscure the measured overlay mark formed by photomask Y0 during patterning of bottom conductors 200, as shown in
Similarly, referring to
It was described earlier how the second use of photomask BC0 during formation of pillars 600 of memory level M1 created an alignment mark, target overlay mark, and measured overlay mark substantially above the alignment mark, target overlay mark, and measured overlay mark created during the first use of photomask BC0 during formation of pillars 300 of memory level M0, and that blocking structures were created at intervening levels to prevent interference between the first and second instance of each reference mark. Photomask BC0 is used a third time to pattern pillars 900 of memory level M2, and, predictably, the same problem of interference arises again.
Referring to
Referring to
Referring to
Referring to
It will be recalled that, while most layers are best aligned to the immediate previous layer, zia 450 made contact to routing layer V2, and thus was aligned to it (as shown in column 6 of
Referring to
In most of the pattern and etch steps described so far, the layer to be etched is covered with a blanket of photoresist. The photomask defines features and reference marks. After the exposure and developing process, positive photoresist features remain, including, for example, pillars or rail-shaped conductors and reference marks such as, for example, alignment and inner and outer frame overlay marks.
The zia etch is preferably performed somewhat differently, however. In this case the entire surface is covered with photoresist and only the voids in which zias are to be formed are removed during the developing process. Overlay marks are formed negatively as well. For example, after the exposure and developing steps, the measured overlay mark, preferably an inner frame, is formed as a frame-shaped void in the photoresist, not as a positive feature. When the etch is performed to create the zia voids, the inner frame measured overlay mark creates a void in the dielectric in the shape of the inner frame.
Note also that this dielectric etch is very deep.
Referring to
After formation of bottom conductors 500, dielectric fill will be deposited, reducing topography. A blocking structure can practically be formed with the next layer, then, which is the polysilicon stack that will be patterned into pillars 600. It will be recalled that all of the pillars are patterned with photomask BC0, which is reused to pattern pillars 300, 600, 900, and (eventually) 1200. This blocking structure will thus comprise a polysilicon stack 60 and a titanium nitride barrier layer 62 (in
The size and placement of this blocking structure is crucial. The blocking structure is intended to be patterned with pillars 600. Referring to
In this case, a first overlay mark and a second overlay mark have been formed, the second above the first, with a blocking structure vertically interposed between them. A third overlay mark is below the blocking structure, wherein the second overlay mark is adapted to fit inside the area of the third overlay mark when viewed from above, and wherein the blocking structure does not obscure the third overlay mark.
Larger polysilicon structure are not so prone to peeling as large tungsten structures, however, so this polysilicon blocking structure can be a solid pad rather than a series of parallel lines.
As shown in
Turning back to
Turning to
Referring to
Fabrication continues with a final dielectric etch to form zias (not shown) connecting top conductors 1300 to lower memory levels, patterning of top metal (not shown) using photomask TM, and formation of a pad using photomask PAD. This is the first use of each of these photomasks, so no interference with earlier reference marks takes place, and no further blocking structures need be formed.
Detailed methods of fabrication have been described herein, but any other methods that form the same structures can be used while the results fall within the scope of the invention. It will also be understood that the example provided is only one embodiment. Certain blocking structures could have been formed at different points in the structure. The blocking structures described herein were either a polysilicon pad or a plurality of parallel metal lines, but clearly a blocking structure could take many other forms, so long as it served to obscure a prior recurrence of a reference mark, by masking the mark optically, by preventing the transfer of detectable transferred topography, or by some other method.
Similarly, those skilled in the art will appreciate that the monolithic three dimensional memory array described herein is just one example of an integrated circuit in which photomasks are reused. A four-level memory comprising pillars and rail-shaped conductors was described. Other types of memories having layers or elements different from the ones described here, or non-memory structures, could use blocking structures according to the methods of the present invention to allow reuse of photomasks in formation of a complex integrated circuit.
Chen, Yung-Tin, Radigan, Steven J., Petti, Christopher J., Kumar, Tanmay
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